18 research outputs found

    Assessing sustainability in housing LED urban regeneration : insights from a housing association in Northern England

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    How far do current assessment methods allow the thorough evaluation of sustainable urban regeneration? Would it be useful, to approach the evaluation of the environmental and social impacts of housing regeneration schemes, by making both hidden pitfalls and potentials explicit, and budgeting costs and benefits in the stakeholders’ perspective? The paper aims at answering these questions, by focusing on a case study located in the Manchester area, the City West Housing Trust, a nonprofit housing association. Drawing from extensive fieldwork and including several interviews with key experts from this housing association, the paper first attempts to monetize the environmental and social value of two extant projects – a high-rise housing estate and an environmentally-led program. It then discusses whether and how a stakeholder-oriented approach would allow more engagement of both current and potential funders in the projects at hand. Findings from both the literature and the empirical data that was gathered show how in current housing regeneration processes, room for significant improvements in terms of assessment methods still exist. Findings additionally show that the environmental and social spillovers are largely disregarded because of a gap in the evaluation tools. This may also hinder the potential contributions of further funders in the achievements of higher impacts in terms of sustainability

    Historical Development of the Cameca EPMA

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    Microanalyse et hydrothermalisme oceanique. Premiers resultats et perspectives dans le domaine de la biologie

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    Specimens of hydrothermal vent organisms, Alvinella caudata and Bathymodiolus thermophilus were collected in 1982 from 13 degree N and 103 degree W, on the East Pacific Rise at a depth of 2600 m. The elemental composition was determined for some of their soft tissues at the structural and ultrastructural levels. Two microanalytical methods were used: secondary ion mass spectrometry and X-ray spectrometry. As examples, external and digestive epithelium and lumen of the digestive tract of Alvinella caudata and the gill and digestive gland of Bathymodiolus thermophilus were investigated. Intracellular localization of the elements, performed by electron microscopy, showed that spherocrystals and lysosomes were the target organelles of metal concentration. Moreover, bacteria were shown to be capable of elemental concentration. The correlations between the metal concentrations within the vent organisms and the metal concentrations characteristic of the vent environment are examined

    Stable isotope composition (δ 2 H, δ 18 O AND δ 17 O) of rainfall in Benin, West Africa

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    International audienceThe rainfall isotopic composition, which is a prerequisite for any isotope water cycle study, is generally characterized by important spatial and temporal variations. While δ18O or δ2H are driven, at first order, by the Rayleigh distillation mechanism, leading to a progressive decrease as vapor condensation progresses (leading to the so-called amount, orographic, and continental effects), the combination of both tracers (d-exc = δ2H – 8 x δ18O) generally informs about vapor sources and mixing processes. In tropical areas, the rainfall isotope composition is largely controlled by convective processes associated with the monsoon. Nevertheless, the huge observed variations reflect complexatmospheric processes, from the initial water vapor formation above the ocean until the final rainfall drop at the soil surface, making it difficult to decipher simple dominant controls. These processes combine different phase changes (e.g. condensation processes in the clouds, rainfall re-evaporation) and mixing between different vapor masses, including continental vapor produced by evaporation and plant transpiration.Recent studies highlighted the added-value of using an additional tracer, namely the 17O-excess of water (17O-excess = ln (δ17O + 1) – 0.528 × ln (δ18O + 1)) for characterizing evaporative processes in rainfall (e.g. Luz and Barkan, 2010; Landais et al 2010 ; Tian et al., 2018), surface water (Surma et al., 2015; Surma et al., 2018), and plant water (Landais et al., 2006; Li et al., 2017; Alexandre et al., 2018). In contrast to d-exc, and except at very high latitudes, the 17O-excess is not significantly impacted by temperature and is much less sensitive to Rayleigh distillation processes. Its variations aretherefore principally driven by evaporation processes and may provide key information on evaporation rates, relative humidity conditions, and more generally non-equilibrium processes. In rainfall water, small variations in 17O-excess are expected, mainly controlled by evaporation conditions at the oceanic water source (Luz and Barkan, 2010). In convective monsoon systems, raindrop re-evaporation may play an additional control (Landais et al., 2010). However available data are still insufficient to fully characterize and understand this tracer in atmospheric water. n this study, we characterize the stable isotope compositions (δ2H, δ18O and δ17O) of rainfall in the monsoonal sudanian climatic zone of Benin (West Africa) from two sampling stations installed in April and June 2018. The first station is located at the University of Abomey-Calavi in Cotonou (lat. 6°26’ N; long. 2°21’ E, sampling every ten days), close to the shoreline of the Gulf of Guinea. The second station is located 400 km northern, ‘downwind’ from the main oceanic air mass trajectories, in the AMMA-Catch observatory site (http://www.amma-catch.org/) in Djougou (lat. 9°44’ N; long. 1°34’ E, bi-weekly sampling). Both stations have an average annual rainfall close to 1200 mm with different seasonal distribution. At Djougou, 90% of the annual rainfall occurs in seven months (April o October), while the rainfall season in Cotonou extends from March to November, and is split into two periods separated by a short dry period (mid-July to mid-September). Stable isotopes of the water molecule (δ2H, δ18O and δ17O) are measured at CEREGE on a WS-CRDS Picarro L2140-i. In addition to a classical δ18O and δ2H characterization of rainfall times series, we will compare the 17O-excess and d-exc seasonal variations at the two stations and investigate how evaporation at the oceanic source, water transport, potential raindrop re-evaporation and relative humidity at the rainfall sites, imprint the isotope signatures. Beyond the rainfall isotope characterization, these results willprovide a rainfall background for explorating the triple oxygen isotopic fractionation at play in the water cycle at the soil/plant/atmosphere interface, in the framework of an ongoing ANR project (HUMI-17, https://www.cerege.fr/fr/2017-anr-humi-17)

    Stable isotope composition (δ 2 H, δ 18 O AND δ 17 O) of rainfall in Benin, West Africa

    No full text
    International audienceThe rainfall isotopic composition, which is a prerequisite for any isotope water cycle study, is generally characterized by important spatial and temporal variations. While δ18O or δ2H are driven, at first order, by the Rayleigh distillation mechanism, leading to a progressive decrease as vapor condensation progresses (leading to the so-called amount, orographic, and continental effects), the combination of both tracers (d-exc = δ2H – 8 x δ18O) generally informs about vapor sources and mixing processes. In tropical areas, the rainfall isotope composition is largely controlled by convective processes associated with the monsoon. Nevertheless, the huge observed variations reflect complexatmospheric processes, from the initial water vapor formation above the ocean until the final rainfall drop at the soil surface, making it difficult to decipher simple dominant controls. These processes combine different phase changes (e.g. condensation processes in the clouds, rainfall re-evaporation) and mixing between different vapor masses, including continental vapor produced by evaporation and plant transpiration.Recent studies highlighted the added-value of using an additional tracer, namely the 17O-excess of water (17O-excess = ln (δ17O + 1) – 0.528 × ln (δ18O + 1)) for characterizing evaporative processes in rainfall (e.g. Luz and Barkan, 2010; Landais et al 2010 ; Tian et al., 2018), surface water (Surma et al., 2015; Surma et al., 2018), and plant water (Landais et al., 2006; Li et al., 2017; Alexandre et al., 2018). In contrast to d-exc, and except at very high latitudes, the 17O-excess is not significantly impacted by temperature and is much less sensitive to Rayleigh distillation processes. Its variations aretherefore principally driven by evaporation processes and may provide key information on evaporation rates, relative humidity conditions, and more generally non-equilibrium processes. In rainfall water, small variations in 17O-excess are expected, mainly controlled by evaporation conditions at the oceanic water source (Luz and Barkan, 2010). In convective monsoon systems, raindrop re-evaporation may play an additional control (Landais et al., 2010). However available data are still insufficient to fully characterize and understand this tracer in atmospheric water. n this study, we characterize the stable isotope compositions (δ2H, δ18O and δ17O) of rainfall in the monsoonal sudanian climatic zone of Benin (West Africa) from two sampling stations installed in April and June 2018. The first station is located at the University of Abomey-Calavi in Cotonou (lat. 6°26’ N; long. 2°21’ E, sampling every ten days), close to the shoreline of the Gulf of Guinea. The second station is located 400 km northern, ‘downwind’ from the main oceanic air mass trajectories, in the AMMA-Catch observatory site (http://www.amma-catch.org/) in Djougou (lat. 9°44’ N; long. 1°34’ E, bi-weekly sampling). Both stations have an average annual rainfall close to 1200 mm with different seasonal distribution. At Djougou, 90% of the annual rainfall occurs in seven months (April o October), while the rainfall season in Cotonou extends from March to November, and is split into two periods separated by a short dry period (mid-July to mid-September). Stable isotopes of the water molecule (δ2H, δ18O and δ17O) are measured at CEREGE on a WS-CRDS Picarro L2140-i. In addition to a classical δ18O and δ2H characterization of rainfall times series, we will compare the 17O-excess and d-exc seasonal variations at the two stations and investigate how evaporation at the oceanic source, water transport, potential raindrop re-evaporation and relative humidity at the rainfall sites, imprint the isotope signatures. Beyond the rainfall isotope characterization, these results willprovide a rainfall background for explorating the triple oxygen isotopic fractionation at play in the water cycle at the soil/plant/atmosphere interface, in the framework of an ongoing ANR project (HUMI-17, https://www.cerege.fr/fr/2017-anr-humi-17)
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